US20020181148A1

US20020181148A1 - Air flow control device and method for multi-disc stack

Info

Publication number: US20020181148A1
Application number: US10/040,215
Authority: US
Inventors: Rodney Dahlenburg; Mark Toffle; Brent Weichelt
Original assignee: Individual
Current assignee: Seagate Technology LLC
Priority date: 2001-06-01
Filing date: 2002-01-02
Publication date: 2002-12-05
Also published as: US6937433B2

Abstract

An air flow control device for reducing turbulence on a rotating multi-disc stack. Air flow control device includes a first air dam having cavities formed by a series of alternating plate sections forming gaps therebetween adjacent plates. Gaps define cavities capable of receiving discs when disc stack is rotating. A method for writing data onto an annular writeable surface of a plurality of discs including the steps of mounting the plurality of discs into a coaxial stack, extending one or more dam plates each between a consecutive pair of the plurality of discs and adjacent at least a selected one of the writeable surfaces; and writing data onto the selected surface while a first one of the dam plates overlaps enough of the selected surface so that the first dam plate limits a windage-induced error in the written data.

Description

RELATED APPLICATIONS

This application claims the benefit of priority of U.S. provisional application Serial No. 60/295,275, filed Jun. 1, 2001.[0001]

FIELD OF THE INVENTION

This invention relates generally to the field of digital data storage devices, and more particularly, but not by way of limitation, to a device for controlling air flow near the write heads in a multi-disc servowriter.

BACKGROUND OF THE INVENTION

Modern data handling and storage devices, such as disc drives, are commonly used in a multitude of computer environments to store large amounts of data in a form that is readily available to a host computer. Generally, a disc drive has a magnetic disc, or two or more stacked magnetic discs, that are rotated by a motor at high speed. Each disc typically has two data storage surfaces each divided into a series of generally concentric data tracks where data is stored in the form of magnetic flux transitions.

A data transfer member such as a magnetic transducer or “head” is moved by an actuator arm to selected positions adjacent the data storage surface to sense the magnetic flux transitions in reading data from the disc, and to transmit electrical signals to induce the magnetic flux transitions in writing data to the disc. The active elements of the data transfer member, such as magnetoresistive head element and an interactive write element, are supported by a suspension structure extending from the actuator arm. The active elements fly at a height slightly above the data storage surface upon an air bearing generated by air currents caused by the spinning discs.

A continuing trend in the industry is toward ever-increasing data storage capacity and processing speed while maintaining or reducing the physical size of the disc drive. Consequently, the data transfer member and supporting structures are continually being miniaturized, and data storage densities are continually being increased. The result is an overall increased sensitivity to excitation both from external sources and from self-excitation sources, which adversely affect the positioning control systems moving the actuator relative to the spinning discs.

One such source of excitation results from air currents moving within the disc stack and impinging on disc drive components. Kinetic energy of the rotating discs is transferred by a shearing action through the boundary layer at the air/disc interface to impart movement to air mass within the disc stack, thereby inducing air currents. The air currents generally spiral outwardly, as the disc rotation imparts a rotational force component and as centrifugal force imparts a radial force component. The velocity is related to the radial location; that is, air moving near the disc axis of rotation moves relatively slowly, and is more likely a laminar flow. As the radial distance from the axis of rotation increases, the currents move faster and become more likely a turbulent flow. In either case, when the currents impinge upon an object, such as the data transfer member and/or the actuator, turbulence is likely. Turbulence can impart adverse vibrations, or aerodynamic excitation, to the discs (flutter) and/or to the actuator, particularly to the suspension members (buffeting). Turbulence can also be created by shedding vortices action on the actuator as the currents flow past the actuator, and acting on the disc as the currents are expelled from the disc stack.

Disc stacks are also becoming used is in servo-writing operations where discs are written with servo data before the discs are placed into a head-disc assembly. To increase throughput from such servowriting operations, the number of discs placed on a disc stack is being increased. Also, as data density on the discs increases, more precise control of the disc stack during write operations is required. Because the quality of the data written to the discs depends, in part, on the position stability of the write heads as they fly over the disc surfaces, there is a need for a method and device to reduce turbulence in the vicinity of the write elements and the assemblies on which the write elements are carried. The present invention, described below, provides a solution to this and other problems, and offers other advantages over the prior art.

SUMMARY OF THE INVENTION

Against this backdrop the present invention has been developed. In one exemplary embodiment, the invention is directed to a data handling system including a plurality of discs operably mounted to a spindle assembly. The spindle assembly is capable of rotating the plurality of discs. The data handling system further includes means for supporting at least one stationary baffle extending between two of the plurality of discs while the discs rotate, so as to reduce any windage-induced disturbance.

Another embodiment is an air flow control device for a data handling system in which the data handling system has a stack of rotating discs on a spindle, each recording surface of each disc having a corresponding transducer adjacent thereto for operably reading data from and writing data to the corresponding recording surface. The air flow control device has an air dam including a first baffle arrangement having a plurality of spaced plate sections disposed transverse from an inner wall of the air dam. The plate sections are substantially parallel and forming gaps therebetween adjacent plate sections, each gap capable of receiving a corresponding disc therein when the air dam is engaged with the disc stack.

In another exemplary embodiment, the invention is directed to a method of writing data onto an annular writeable surface of a plurality of discs. The method includes mounting the plurality of discs into a coaxial stack. Next, one or more dam plates are each extended between a consecutive pair of the plurality of discs and adjacent at least a selected one of the writeable surfaces. Data is then written onto the selected surface while, at least first one of the dam plates overlaps enough of the selected surface so that the first dam plate limits a windage-induced error in the written data.

These and various other features as well as advantages which characterize the present invention will be apparent from a reading of the following detailed description and a review of the associated drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a multi-disc writer incorporating an example embodiment of an air flow control device of the present invention. [0012]
FIG. 2 is a close up perspective view of the multi-disc writer shown in FIG. 1 with the disc spin motor removed. [0013]
FIG. 3 is a perspective front view of the air flow control device of FIG. 1. [0014]
FIG. 4 is a rear perspective view of the air flow control device of FIG. 1. [0015]
FIG. 5 is a side elevational view of a section of the air flow control device of FIG. 1, shown engaging a disc stack. [0016]
FIG. 6 is a bottom view of a portion of the air flow control device of FIG. 1. [0017]
FIG. 7 is another example embodiment of an air flow control device of the present invention.[0018]

DETAILED DESCRIPTION

Referring now to FIGS. 1 and 2, shown is a [0019] multi-disc writer 100 incorporating an example embodiment of an air flow control device 200 of the present invention. This multi-disc writer 100 is used to write servo data to a multi-disc stack 110 of discs 112. Each disc 112 has at least one and preferably two writeable surfaces 180. The disc stack 110 is mounted on a drive motor spindle assembly 102 driven by a motor 104. The disc stack 110 can be removed and mounted to the motor 104 using the spindle assembly 102 which can be repeatedly removed from the motor 104 and replaced with a new disc stack 110 whenever it is desired to write data to a new disc stack 110. A plurality of discs 112 can be written simultaneously by engaging the actuator assembly 120 containing write heads (not shown) located on the actuator assembly 120. The actuator assembly 120 containing write heads can be indexed to write one or both surfaces 180 of each disc 112 in the disc stack 110.
The [0020] multi-disc writer 100 includes an air flow control device 200 for reducing air flow in the region of the actuator assembly 120 write heads 121 (shown in FIG. 2) when the heads are engaged to write discs 112 in the disc stack 110. In the example embodiment shown, the air flow control device 200 includes a dam 210 and a stripper 220. Referring to FIG. 5, the air flow control device 200 is shown engaging the disc stack 110. With the air flow control device 200 engaged, discs 112 in the disc stack 110 rotate counterclockwise, that is, in the direction of arrow R. The dam 210 includes a leading edge section 212 wherein the rotating discs 112 are moving into the leading edge 212 relative to the direction R of disc rotation. A high-pressure zone 214 is created where the dam 210 retards air from entering the leading edge 212 of the dam 210. The stripper 220, also in an engagement position, reduces air flow created by the discs 112 in direction of the heads 121 of actuator assembly 120.
Referring to FIGS. 5 and 6, the [0021] dam 210 includes a stationary baffle arrangement 215 having a series of alternating gaps 218 and plates 219. The dam also includes an outer section 211 having an inner wall 260. The gap 218 defines a cavity having an outer boundary 240, a first edge 244 and a second edge 246 and an inner boundary 242. The outer boundary 240 is bounded by the inner wall 260 and is generally arcuately shaped. The cavities formed by the gaps 218 are preferably wedge-shaped sections approximating that of section of the disc 112 which is contained within cavity. The first and second edge boundaries 244, 246 extend transversely from the inner wall 260 of the outer boundary 240 of the dam 210. The first edge 244 creates a high pressure zone 214 when the discs 112 are rotating. The dam 210 can be engaged and disengaged to disc stack (not shown) by rotating the dam 210 around the dam pivot assembly 216. In the example embodiment shown in FIGS. 1 and 2, to obtain the open or disengagement position, the dam 210 is pivoted away from the discs 112 around the pivot assembly 216.
Referring to FIGS. 3, 4 and [0022] 5, the stripper 220 includes a stripper pivot assembly 236, which allows the stripper 220 to be engaged and disengaged from the discs 112 in the disc stack 110. The stripper 220 also includes a second stationary baffle arrangement 225 having a series of alternating gaps 227 and plates 229. The gap 227 defines a cavity having an outer boundary 231, an inner boundary 233, a first edge 235 and a second edge 237. The outer boundary 231 is arcuately shaped, preferably being a wedge-shaped section approximately a section of the disc 112 that is contained within the cavity. The first and second edges 235, 237, extend transversely from an inner wall 239 of the outer boundary 231 of the stripper 220. The second edge 237 reduces air that is entrained by rotating discs 112 that impact the heads 121, thereby reducing or eliminating writing errors. Referring again to FIGS. 1 and 2, the dam 210 and the stripper 220 are shown disengaged from the disc stack 110. In this position, the spindle assembly 102 can be removed from the motor 104 and a replacement spindle assembly 102 containing a new disc stack 110 to be written by the heads (not shown) in the actuator assembly 120 can be inserted into the motor 104 without interference by the dam 210 and the stripper 220. The dam 210 is then engaged to the disc stack 110 by rotating dam around the pivot assembly 216 until the dam 210 is positioned on disc stack as desired. Similarly, the stripper 220 is engaged to the disc stack 110 by rotating it around the stripper pivot assembly 236 until the stripper 220 is in desired position proximate to the disc stack 110.
The [0023] dam 210 and the stripper 220 include a plurality of alternating plates 219, 229, respectively, and gaps 218, 227, respectively, and each gap 218, 227 forms a cavity that is approximately wedge shaped. Preferably, each cavity receives the discs 112, and when surrounding 112 disc, there is preferably a clearance of 0.040 inches at the outer diameter of disc the 112. Preferably, clearance is 0.015 inches from either side of the disc 112 surfaces. The inner boundaries 242, 233 of the dam 210 and the stripper 220, respectively, are preferably arcuately shaped.
Referring to FIG. 4, the [0024] dam 210 and the stripper 220 of the air flow control device 200 are operably engaged and disengaged using engaging assembly 300. The engaging assembly 300 is preferably hydraulic or pneumatic cylinder that can be coupled and controlled via electronic circuitry through the main controls of the multi-disc writer 100. The engaging assembly 300 includes an arm member 302 that engages cam 304 coupled to the pivot assembly 216 of the dam 210. Referring now to FIGS. 3 and 4, movement of the arm 302 rotates the cam 304. A linkage 306 is coupled to and follows movement of the cam 304. Thus when the arm 302 is positioned in an open position by the engaging assembly 300, the cam 304 and the linkage 306 are actuated such that the dam 210 and the stripper 212 are disengaged from the disc stack 110 of the multi-disc writer 100. Alternatively, when the arm 302 of the engaging assembly 300 is in closed position, the cam 304 and the linkage 306 operably rotate the dam 210 and the stripper 212 around their respective pivot points 216, 236. Referring to FIG. 6, gap 218 between adjacent plates 219 is preferably 0.070 inches.
Referring to FIG. 5, when the [0025] dam 210 and the stripper 220 are engaged to the disc stack 110, air flow around and between the discs 112 is reduced because a significant portion of the air space between the discs is now replaced by plates 219, 228 as discs 112 are received into cavities formed by gaps 218, 227. This reduces the radial and tangential air flow in the disc stack 110, thereby reducing the turbulence in the region of the write heads 122 of actuator assembly 120.
The [0026] dam 210 and the stripper 220 can be fabricated using various techniques. One method is to begin with a solid block of material for each section and electrodischarge machine the part. Machining in this manner allows the surface finish, which controls and affects turbulence, to be machined to exact tolerances. Furthermore, this method also allows the gap 218, 227 width between adjacent plates 219, 229 to be controlled. An example of the materials that could be used for the dam 210 and the stripper 212 of the example embodiment of the present invention include 300 and 400 Series stainless steel, electroless nickel-plated steel or aluminum or tool steel.
Alternatively, pins could be used to stack plates on pins separated by spacers. Referring to FIG. 7, shown as an alternative embodiment of an air flow control device of the present invention, an air [0027] flow control device 500 includes a base section 502 including a series of slots 504. The slots 504 receive the plates 506 having a wedged shaped section 510. Adjacent plates 506 form gaps 508 for receiving discs (not shown) in disc stack (not shown). The air flow control device 500 can be engaged and disengaged to disc stack by placing guide 511 on indexing device (not shown) thereby allowing air flow control device to move along indexing device.
Another aspect of the present embodiment is direct to a method of writing data onto an annular writeable surface of a plurality of discs. Discs are mounted into a coaxial stack. One or more dam plates are extended between a consecutive pair of the plurality of discs and adjacent to at least one of the writeable surfaces. Data is then written onto the selected surface while a first one of the dam plates overlaps enough of the selected surface so that the first dam plate limits a windage induced error in the written data. Preferably, the first dam plate overlaps at least 10 percent of the selected surface. [0028]
In another embodiment, the method can further include removing the plurality of discs from the coaxial stack and mounting the disc having a selected surface into the data handling system. The method further includes mounting the first dam plate on a base so that the first dam plate is pivotable about a first axis of rotation and also mounting a second one of the dam plates on the base so that the second dam plate is pivotable about a second axis of rotation. The method further includes writing many servo reference marks on the selected surface. [0029]
Alternatively characterized, another embodiment of the present invention is an air flow control (such as [0030] 200) device for a data handling system (such as 100). The data handling system (such as 100) includes a disc stack (such as 110) having a plurality of rotating discs (such as 112) on a spindle (such as 102). Each disc (such as 112) has at least one recording surface (such as 180) and each recording surface (such as 180) has a corresponding actuator assembly (such as 120) for operably reading data from and writing data to the corresponding recording surface (such as 180).
In yet another embodiment, the air flow control device (such as [0031] 200) includes a first air dam (such as 210) having an outer section including an inner wall and an outer wall. The air flow control device (such as 200) further includes a plurality of spaced plate (such as 219) sections disposed transverse from the inner wall of the outer section. The plate (such as 219) sections are substantially parallel and form gaps (such as 218) therebetween adjacent plate (such as 219) sections. Each gap (such as 218) forms a cavity that is capable of surrounding a corresponding section of a disc (such as 112) when the air dam (such as 210) is engaged with the disc stack (such as 110). Each gap (such as 218) defining a cavity further includes an outer boundary (such as 240), a first edge boundary (such as 244), a second edge boundary (such as 246) and an inner boundary (such as 242). The outer boundary (such as 240) is preferably arcuately shaped and formed along the inner wall of the outer section. The first and second edge boundaries (such as 244, 246) extend transversely from the inner wall of the outer section, and the first edge boundary (such as 244) has a first end and a second end and the second edge boundary has a third and a fourth end. The inner boundary (such as 242) is generally arcuately shaped to accommodate disc clamp (such as 200) and extends between the second end of the first edge boundary and the fourth end of the second edge boundary. Additionally, the air flow control device (such as 200) can also include a second air dam section, (such as 220) such as a stripper.
In another example embodiment, the present invention is directed to a method of writing data onto an annular writeable surface of a plurality of discs. The method includes a step of mounting the plurality of discs into a coaxial stack. Next, one or more dam plates are each extended between a consecutive pair of the plurality of discs and adjacent at least a selected one of the writeable surfaces. The method further includes a step of writing data onto the selected surface while a first one of the dam plates overlaps enough of the selected surface so that the first dam plate limits a windage-induced error in the written data. [0032]
In still another embodiment, the invention is directed to a data handling system (such as [0033] 100) including a plurality of discs (such as 112) operably mounted to a spindle assembly (such as 102). The spindle assembly is capable of rotating the plurality of discs (such as 112). The data handling system (such as 100) also includes means for supporting at least one stationary baffle extending between two of the plurality of discs while the discs rotate, so as to reduce a windage-induced disturbance.
It will be clear that the present invention is well adapted to attain the ends and advantages mentioned as well as those inherent therein. While a presently preferred embodiment has been described for purposes of this disclosure, various changes and modifications may be made which are well within the scope of the present invention. For example, the baffle arrangement can be fabricated to combine the dam and stripper sections into a unitary arrangement. Numerous other changes may be made which will readily suggest themselves to those skilled in the art and which are encompassed in the spirit of the invention disclosed and as defined in the appended claims. [0034]

Claims

What is claimed is:

1. A data handling system comprising:

a base deck having a spindle motor mounted to the base deck, the spindle motor having a central axis; and

a disc stack having a plurality of data discs mounted to the spindle motor for rotation about the central axis, each disc having at least one recording surface;

a first air dam for engaging the disc stack, the first air dam having an outer section having an inner wall and an outer wall; and

a plurality of spaced plate sections disposed transverse from the inner wall of the outer section, the plate sections being substantially parallel and forming one or more gaps therebetween adjacent plate sections, each gap capable of surrounding a corresponding disc when the air dam is engaged with the disc stack.

2. The data handling system of claim 1 further including:

a second air dam having a plurality of spaced apart second plate sections, the second plate sections being substantially parallel and forming one or more gaps therebetween adjacent second plate sections;

each gap between adjacent plates section defining a space capable of receiving a corresponding disc, each space enclosing a section of the corresponding disc, wherein a section of the corresponding disc is contained within the space; and

wherein the each gap on the first air dam has a corresponding gap on the second air dam, and wherein the corresponding gaps enclosed a corresponding disc when the disc is enclosed with the gaps on the first and second air dams.

3. The data handling system of claim 1, further including:

an articulating arrangement for operably engaging and disengaging the air dam with the discs, wherein each disc is partially enclosed and free to rotate within a corresponding cavity when the air dam is engaged.

4. The data handling system of claim 1, further including:

an articulating arrangement for operably engaging and disengaging the first and second air dams with the discs, wherein each disc is partially enclosed and free to rotate within a corresponding cavity when the air dams are engaged.

5. The data handling system of claim 11, wherein the air dam includes a plurality of slots and each a corresponding plate is retained in each slot.

6. The data handling system of claim 5, further including spacers between adjacent plate sections.

7. The data handling system of claim 1, wherein the inner wall is arcuately shaped and defined by a 180 degree angle.

8. A method of handling data comprising of:

(a) mounting the plurality of discs into a coaxial stack;

(b) extending one or more dam plates each between a consecutive pair of the plurality of discs and adjacent to at least a selected one of the writeable surfaces; and

(c) writing data onto the selected surface while a first one of the dam plates overlaps enough of the selected surface so that the first dam plate limits a windage-induced error in the written data.

9. A method of claim 8, the method further including steps of:

(d) removing the plurality of discs from the coaxial stack; and

(e) mounting the disc having the selected surface into the data handling system.

10. The method of claim 8 in which the extending step (b) includes steps of:

(b1) mounting the first dam plate on a base so that the first dam plate is pivotable about a first axis of rotation; and

(b2) mounting a second one of the dam plates on the base so that the second dam plate is pivotable about a second axis of rotation.

11. The method of claim 8 in which the writing step (c) includes a step (c1) of writing many servo reference marks on the selected surface.

12. The method of claim 8 in which the extending step (b) causes the first dam plate to overlap at least 10% of the selected surface.

13. A data handling system comprising:

a plurality of discs operably mounted to a spindle assembly, the spindle assembly capable of rotating the plurality of discs; and

means for supporting at least one stationary baffle extending between two of the plurality of discs while the discs rotate, so as to reduce a windage-induced disturbance.

14. The data handling system of claim 13, wherein the means for reducing turbulence includes first and second air dam sections.

15. The data handling system of claim 14 further including:

an articulating arrangement for operably engaging and disengaging the first and second air dam sections with the discs, wherein each disc is partially enclosed and free to rotate within a corresponding cavity when the air dams are engaged.